This is the Realm of Simply Beautiful Art

Simply Beautiful Art

00:40

@Deedlit I see you like some anime

Simply Beautiful Art

01:39

@Deedlit Man, its very hard for me to understand some of the ordinal collapsing functions, since my understanding of the logic symbols is horrible

Ovi

02:55

@SimplyBeautifulArt Which logic symbols are you talking about?

Simply Beautiful Art

googology.wikia.com/wiki/…

@Ovi Too much stuff nested together, it is all very complicated, as it is the first time I've seen such symbols

Ovi

ah

yeah I've been trying to read it for 5-10 minutes

it's very difficult xD

Simply Beautiful Art

XD

Madore's psi function

I understand that one due to working with it

(God lord save us when we put this stuff in the fast growing hierarchy)

Deedlit

03:35

@SimplyBeautifulArt Yeah, dense mathematical notation can be very difficult at first

Please tell me if there's anything I can help you with

Simply Beautiful Art

meh. Perhaps a resource

Deedlit

Have you seen my series of blog posts on OCFs?

googology.wikia.com/wiki/User_blog:Deedlit11?page=2

Simply Beautiful Art

I believe so? (?)

oh, no I haven't

Thanks!

Xam

19:59

Hello (?)

Fine Man

Hello (!)

Xam

Hello @FineMan first time I see you here xd

Fine Man

Why thank you Good Sir, @Xam. :)

I was formerly @SirJony

So you might've seen him.

Xam

Yeah I think so :)

Can I ask you something?

Fine Man

Sure. You just did.

;)

Xam

20:13

What are your areas of interest in mathematics?

Simply Beautiful Art

@Xam hey man

Haha

You look lonely @Xam

Xam

Oh hello @SimplyBeautifulArt

Yeah, I can't find people who is interested in abstract algebra xD

Fine Man

@Xam -- Well, I frankly don't know. I'm not planning to pursue a math degree, so I'm probably not into math as others. However, I do like geometry (I'm currently trying to solve a puzzle given to me by a mathematician). But I really can't wait until I learn Taylor series.

Simply Beautiful Art

@FineMan is not even at that course yet sadly @Xam

Fine Man

Nope. No abstract algebra for me. :)

Simply Beautiful Art

20:15

@FineMan really? You can't wait?

Xam

Oh I see :/

Simply Beautiful Art

@Xam well

Did I already tell you about large numbers?

Fine Man

Once I done with solving those darned limits I'll fly through differentiation and get to Taylor.

Simply Beautiful Art

@FineMan and why wait? =D

Oh

Xam

Anyways, can I ask you both of you a problem?

Simply Beautiful Art

20:16

Never mind

Sure @Xam

Xam

@SimplyBeautifulArt no, you didn't

Simply Beautiful Art

In return, can I ask you about large numbers?

Xam

You can tell me about large numbers :)

Simply Beautiful Art

Large numbers are more or a story IMO

Fine Man

@Xam -- I've heard enough of @SimplyBeautifulArt and his large numbers, ask us your problem. :)

Simply Beautiful Art

20:20

But anyways, while you ask us your problem, I ask you: "what is the largest number you could write on a sheet of paper?"

Xam

Well, this is something basic but I can not figure out the formal argument. Let's say we have a matrix $ M $ such that there is exactly one $ 1 $ in each column and in each row. Then $ M $ is a square matrix.

Simply Beautiful Art

Lol @FineMan

Xam

XD

Simply Beautiful Art

Ok, continue

Fine Man

@Xam -- I don't have the answer, but some reducto ad absurdum might make the proof simplier.

Simply Beautiful Art

20:21

Oh, wait, that's it?

Fine Man

I assumed so. :P

Simply Beautiful Art

Isn't it just a one by one matrix by definition?

Xam

Sorry, the matrix is $mxn$.

Simply Beautiful Art

I don't understand the question then

Xam

Here is my idea: if we count by rows we have $m$ 1's and if we count by columns we have $n$ 1's, then $m=n$. Is that right?

Fine Man

20:23

I think he means
0 0 0 1
0 1 0 0
1 0 0 0
0 0 1 0

Xam

Lol

Yes, exactly @FineMan

Fine Man

(replace 0's with random nums)

Xam

We have to prove that $m=n$.

Fine Man

Maybe.

Hold on. I'll BRB.

Xam

My idea was to use double counting. Count by rows and by columns.

Simply Beautiful Art

20:25

It looks trivial, but I don't know what proofs are

Xam

@SimplyBeautifulArt what does "what is the largest number you could write on a sheet of paper?" mean?

Simply Beautiful Art

I mean try to write the largest number you can on a sheet of paper. For example, 100000000!!!!!!!!

(Factorial = !)

You may also use any made up function as long as you properly define it

Xam

Well, I suppose I can take googol!

Simply Beautiful Art

But that definitely doesn't use the full paper

Fine Man

(Hint: use superultramegahyperoperations)

Simply Beautiful Art

20:30

Lmao, great description @FineMan

Fine Man

Or just hyperoperations. Your choice. :)

Xam

Then I don't know how to make such a large numbers xD

What are "hyperoperations"?

Simply Beautiful Art

Simple

Fine Man

I didn't know until Simply told me yesterday.

Here comes the description... drumroll for Simply!!!

Simply Beautiful Art

The first hyperoperation is addition

The second is repeated addition, or multiplication

The third is ... Which is exponentiation

The fourth is... Repeated exponentiation

Etc.

Mildly large numbers come out of this

@Xam Do you know ordinals and fundamental sequences?

Xam

20:33

So that is an iteration of addition, multiplication and exponentiation?

Simply Beautiful Art

Yes

it is repeated operations of the previous operation

hence the name hyper-operation

Xam

Nope, I don't know :(

Simply Beautiful Art

Well, we can actually produce numbers larger than anything you could feasibly represent in hyperoperators

Xam

Using ordinals?

Simply Beautiful Art

Do you have MathJax running @Xam ?

Xam

20:35

Yes

Simply Beautiful Art

Yes, using ordinals. =D

Xam

Ordinals like $\omega$?

Simply Beautiful Art

Yes.

Well, we have a function defined as follows:

$f_0(n)=n+1$

$f_{\alpha+1}(n)=\underbrace{f_\alpha(f_\alpha(\dots f_\alpha(n)\dots))}_{n\ f_\alpha's}$

$f_\alpha(n)=f_{\alpha[n]}(n)$

Basically, we define $\omega$ as follows:

$\omega=\sup\{1,2,3,\dots\}$

Then $\omega[n]$ is the nth term of it's defined sequence

For example, $\omega[3]=3$

Now, the fun part. First of all, for whole numbers $k$, we have
$$f_k(n)\approx H_{k+1}(n,n)$$

where $H_k$ is the $k$th hyperoperator with $k=0$ being $a+b$.

We then have, using our $\omega$,
$$f_\omega(n)=f_{\omega[n]}(n)=f_n(n)$$

Still not too bad. You can still approximate this in terms of hyperoperators. But then we have

Xam

And that function produces large numbers?

Simply Beautiful Art

$$f_{\omega+1}(n)=\underbrace{f_\omega(f_\omega(\dots f_\omega(n)\dots))}_n$$

@Xam Yes, would you like to see an explicit example?

Fine Man

20:41

Hate to interrupt all these dollar signs, but how do you activate MathJax in chat?

Xam

That's something interesting :D

@FineMan github.com/vyznev/chatjax

I use that script

Simply Beautiful Art

@FineMan Or tinyurl.com/cfqcvpc

@Wojowu Hi, explaining the FGH to some pepes

Xam

I supposed to be better than Robjohn's script

It's supposed*

Simply Beautiful Art

A small demonstration:
$$f_{\omega+1}(3)=f_\omega(f_\omega(f_\omega(3)))=f_\omega(f_\omega(f_3(3)))\approx f_\omega(f_\omega(H_4(3)))$$

Fine Man

What browser do you use?

Simply Beautiful Art

20:43

Chrome

Xam

@SimplyBeautifulArt what is FGH? I can't figure out.

Opera

Simply Beautiful Art

@Xam Fast growing hierarchy

Xam

Ah I see xd

Simply Beautiful Art

Note that $$H_4(3)=3^{3^{3^3}}$$

Xam

Yeah?

Simply Beautiful Art

20:44

$$\approx10^{3\text{ trillion}}$$

Fine Man

OMG! No more dollar signs in chat!! :D

Simply Beautiful Art

@FineMan I KNOW!!! BEST THING EVER

Xam

FGH is related to "computability theory, computational complexity theory and proof theory"

Simply Beautiful Art

Yes, it is very useful

Xam

Wow, that's something I would like to learn

@SimplyBeautifulArt how did you learn all that?

Simply Beautiful Art

20:45

Now notice that $$f_\omega(f_\omega(3))\approx f_\omega(10^{3\text{ trillion}})$$

YouTube plus Wikipedia. And I didn't learn ALL of that

Xam

@FineMan it's great, right?

Simply Beautiful Art

$$=f_{10^{3\text{ trillion}}}(10^{3\text{ trillion}})$$

So we saw that $f_3(3)$ was humongous, right?

(@Wojowu Actually, I think I may have done a small calculation error lol, but they get the point)

Xam

Yes, that's right :D

Fine Man

It's epic. And does this work on other sites?

Simply Beautiful Art

So This is humongous

Fine Man

20:47

Not just SE?

Simply Beautiful Art

@FineMan Yes, it works on any page. Very funny when you go to some economy page with all the dollar signs hehe

Fine Man

LOL.

Simply Beautiful Art

And we're not even done! This is only $f_\omega(f_\omega(3))$. We want to take the $f_\omega$ of that!

And so this is fairly large, but it gets worse

Xam

So you can get something like HUMONGOUS, right?

Simply Beautiful Art

@Xam Do you know Graham's number?

Xam

20:49

No, tell me about it

Simply Beautiful Art

$$f_{\omega+1}(64)>\text{Graham's number}$$

Xam

Wow xd

Simply Beautiful Art

I'll leave that story for another day, since we're already way past Graham's number

Consider the following:
$$f_{\omega+2}(3)=f_{\omega+1}(f_{\omega+1}(f_{\omega+1}(3)))$$

Xam

Ok, no problem

Simply Beautiful Art

Lol, no problem indeed, because we may as well just go straight to $\omega+k$, right?

Xam

20:50

what happens if we use $2\omega$? Can we?

Simply Beautiful Art

Well, we have $\omega2=\sup\{\omega+1,\omega+2,\omega+3,\dots\}$

Thus,
$$f_{\omega2}(3)=f_{\omega+3}(3)$$

Likewise,
$$f_{\omega3}(3)=f_{\omega2+3}(3)$$

Xam

What about $\omega^{\omega}$?

Simply Beautiful Art

etc. you get the main idea

Fine Man

... these $\omega$s are ringing a bell from a vid I watched long ago. When do you get to $\aleph$?

Simply Beautiful Art

Whoa whoa, hold up, we need to define our numbers!

@FineMan That's a completely different type of number, so it can't compare

Fine Man

20:52

I saw a VSauce video on very big numbers. I recall none of it but I do remember there were a lot of greek and hebrew letters. :)

Simply Beautiful Art

First,
$$\omega^2=\sup\{\omega,\omega2,\omega3,\omega4,\dots\}\\2\omega^2=\sup\{\omega^2+\omega,\omega^2+\omega2,\omega^2+\omega3,\dots\}$$

@FineMan Ah, yes... very large numbers. How to count past infinity.

Xam

Oh, I got it.

Simply Beautiful Art

In general, if we have, say, $3\omega^5$, we split it up into $2\omega^5+1\omega^5$, then "diagonolize"

Fine Man

I think I'll watch it again one day, but @Xam might want to see it soon: youtube.com/watch?v=SrU9YDoXE88

Simply Beautiful Art

Diagonolizing is just the process where we write it out and take the nth term for our function's purposes.

@FineMan Xam already knows his ordinals I think

Fine Man

20:55

Oh. OK. Whatever ordinals are. :P

Simply Beautiful Art

Anyways, we may finally reach @Xam 's proposal.
$$\omega^\omega=\sup\{\omega,\omega^2,\omega^3,\omega^4,\dots\}$$

Xam

I read something about ordinals, but I haven't studied it properly.

Simply Beautiful Art

Poof. I think the universe exploded.

Xam

@SimplyBeautifulArt lol

Simply Beautiful Art

But we can go further!

First, I need to define some rules.

Xam

20:56

Yes, do it!

Simply Beautiful Art

$$\omega^{\omega+1}=\omega^\omega\times\omega$$

$$=\sup\{\omega^\omega \times1, \omega^\omega \times2, \omega^\omega \times3,\dots\}$$

Sorry, the MathJax starts to break if I don't put spaces in the coding XD

The key: Always reduce! Then diagonolize!

Now, we can safely do things like this:
$$\omega^{\omega^\omega}$$

Xam

And so on right?

Simply Beautiful Art

When we have things in the exponents that don't reduce down to 'ground level', we must diagonolize the exponents first

Xam

I see

Simply Beautiful Art

$$\omega^{\omega^\omega}=\omega^{ \sup\{\omega, \omega^2, \omega^3,\dots\}}$$

Xam

20:59

@FineMan youtube.com/watch?v=uWwUpEY4c8o you might like this

Simply Beautiful Art

Clearly, we are going to have a crazy time trying to diagonolize this. Anyways, we move on to the next 'level'

This level when put into the fast growing hierarchy produces functions that grow so fast, you can't do basic PA with it:
$$\epsilon_0=\sup\{\omega,\omega^\omega, \omega^{\omega^\omega},\dots\}$$

And then we have our first fixed-point.
$$\omega^{\epsilon_0}=\epsilon_0$$

Funny point in the storyline, because it's not too hard to get past this.
$$\omega^{\epsilon_0+1}=\omega^{\epsilon_0}\omega=\epsilon_0\omega$$

Xam

Epsilon zero? nice

Simply Beautiful Art

We then diagonolize the omega out, which gives us a sum of $\epsilon_0$, which we then diagonolize one by one (and remember folks! Whenever you can, reduce the fast growing hierarchy down by turning it into repeated iterations of itself (see rule 2))

Anyways, we can then produce a higher ordinal!
$$\epsilon_1=\sup\{\epsilon_0+1, \omega^{\epsilon_0+ 1}, \omega^{\omega^{\epsilon_0+ 1}}, \dots\}$$

Xam

That's amusing!

Simply Beautiful Art

Anyways, just absorb how absurdly large this number is after you put it into the fast growing hierarchy

Of course, we move on.
$$\epsilon_2=\sup\{\epsilon_1+1, \omega^{\epsilon_1+ 1}, \omega^{\omega^{\epsilon_1+ 1}}, \dots\}$$

We keep doing this until we reach $\epsilon_\omega$,
$$\epsilon_\omega=\sup\{ \epsilon_0, \epsilon_1, \epsilon_2,\dots\}$$

Xam

21:06

Is HUMONGOUS?

Simply Beautiful Art

moral of the story at this step. You diagonolize the inside part first. Then work your way out, which is how we diagonolize something like this:
$$\epsilon_{\epsilon_0}=\epsilon_{\sup\{ \omega, \omega^\omega,\dots \}}$$

Xam

Interesting.

Simply Beautiful Art

Diagonolize and diagonolize until you can't, then turn, say, the $\epsilon_{\omega+1}$ into $\omega^{\omega^{\epsilon_\omega+1}}$

@FineMan You good there man? XD

@projectilemotion Hey, glad you could stop by lol

Xam

And so on, right?

projectilemotion

@SimplyBeautifulArt Hey, how are you?

Simply Beautiful Art

21:09

Anyways, we reach a totally higher level now:
$$\zeta_0=\sup\{\epsilon_0, \epsilon_{\epsilon_0},\epsilon_{\epsilon_{\epsilon_0}}, \dots\}$$

@projectilemotion I'm doing good, you?

Xam

Wow

Simply Beautiful Art

@Xam And so, we end up with a thing known as Veblen Hierarchy

projectilemotion

@SimplyBeautifulArt Not bad, thanks

Simply Beautiful Art

Which keeps this going forever

Xam

I see

Simply Beautiful Art

21:10

Well, not forever. You kind of stop at $\omega$, because that is like forever, but not, if you get what I mean

And this is where I stop and say Veblen Hierarchy is not enough

Xam

Yeah, I got it

Simply Beautiful Art

Because you can actually produce ordinals so large, they don't fit inside Veblen hierarchy

I believe, in terms of Mor's ordinal collapsing function, the supremum of all (small) Veblen hierarchy is $\psi(\Omega^\omega)$

Which, as you can see, is some pretty compact notation that conveys an unsettling powerful message

Xam

That's amazing.

Simply Beautiful Art

Well, there is an upper bound to $\psi(\alpha)$ though. That is where we introduce $\psi_1(\alpha)$

And you can see where the story goes

Xam

Yes

Thanks for talk about these topics.

Simply Beautiful Art

21:14

If you wish, I can try to explain the ordinal collapsing function, though its going to be much harder than Veblen hierarchy (I think, it was for me)

No problem XD

Xam

Well, right now I have no time :(

Simply Beautiful Art

XD yes, of course. I too wish to do a something else

Xam

Actually, I have to go out

Simply Beautiful Art

because these large numbers give me small headaches

Cya man!

Xam

But, would you allow to post my problem here, maybe someone can help me.

Simply Beautiful Art

21:16

Yes, please repost lol

56 mins ago, by Xam

Well, this is something basic but I can not figure out the formal argument. Let's say we have a matrix $ M $ such that there is exactly one $ 1 $ in each column and in each row. Then $ M $ is a square matrix.

Someone please help @Xam with his problem. Please and thanks!

Xam

Oh thank you!

Simply Beautiful Art

No problem :-)

@Xam Has no one answered it on the main chat?

Xam

$M$ is a $m\times n$ matrix. So basically the problem ask to show that $m=n$.

Simply Beautiful Art

I think @FineMan got lost in the forest above. Maybe I should go back and find him

Xam

@SimplyBeautifulArt I was too embarrassed to ask xd :(

Well, I gotta go!

Simply Beautiful Art

21:19

Cya!

Xam

See you later guys. Have a nice day!

Fine Man

@SimplyBeautifulArt -- Sorry, some bears chased me down the wrong path. Fortunately I knew the way out of the forrest.

Simply Beautiful Art

Haha, glad to hear you are alive!

Fine Man

Missing a leg and a half, but all-in-all, just fine.

;)

Simply Beautiful Art

Tis but a scratch

Fine Man

21:24

Monty Python-The Black Knight

►

Simply Beautiful Art

YES

Fine Man

23:20

@Xam -- I watched that Hydra vid. Very cool!

Simply Beautiful Art

Extremely Large Numbers 1 - Introduction

►

@FineMan This is the intro to large numbers

24 videos of large number madness XD

Transcript for

$Mathematics$ This is the Realm of Simply Beautiful…